IT202000009982A1 - BEARING UNIT WITH ECCENTRIC COLLAR - Google Patents

Description

Description accompanying a patent application for an industrial invention entitled: UNITA? BEARING WITH ECCENTRIC COLLAR

DESCRIPTION

Technical sector of the invention

The present invention ? relating to a?unit? bearing, provided with a collar for tightening the radially internal ring on a rotating shaft. The unit such a bearing? suitable for applications in the manufacturing industry and above all for the agricultural industry as it is simple and cheap to make.

In particular, the unit? bearing according to the present invention ? equipped with rolling elements and ? equipped with an optimized clamping system that involves the use of an eccentric clamping collar, which can? lock both the shaft and the radially internal ring at the same time, making the two components integral with each other.

Known technique

Are they unit notes? bearing equipped with rolling elements and clamping systems of the unit? itself on a rotating shaft.

The units? bearings are used to allow relative motion of one component or assembly with respect to another component or assembly. The unit bearing typically has a first component, such as a radially internal ring, which is? fixed to a first component, such as a rotating shaft, and a second component, such as a radially outer ring, which is attached to a second component, such as a stationary housing. Typically, as per the examples mentioned above, the radially inner ring ? rotating while the radially external ring? stationary, but many applications expect the outer element to rotate and the inner element to be stationary. In any case, in the units? rolling bearing the rotation of a ring with respect to the other ? allowed by a plurality? of rolling elements that are positioned between the cylindrical surface of one component and the cylindrical surface of the second component, usually referred to as raceways. The rolling elements can be balls, cylindrical or conical rollers, needles and similar rolling elements.

Am I otherwise? note the units? bearings equipped with a collet for mounting on a rotating shaft. This solution turns out to be more? simpler and cheaper than the one which foresees the forced coupling by interference of the radially internal ring on the rotating shaft. A known solution consists in adopting an eccentric clamping collar provided with a pressure screw which grips the rotating shaft. At the same time, the eccentric shape of the collar, by rotating the collar itself by a certain angle, makes that you create a cylindrical contact surface between the collar and the rotating shaft as well as? between the collar and the radially internal ring so as to make the rotating shaft, the clamping collar and the radially internal ring integral with each other respectively? bearing.

The use of the eccentric clamping collar for? it has drawbacks related to the noise generated and excessive vibrations which can damage the shaft on which they are installed.

Furthermore, in the case of onerous applications which need to transmit high powers, the gripping performances between the three components (shaft ? collar ? inner ring) are not sufficient. In such conditions, ? It is also possible to disengage and disassemble the clamping collar from the radially internal ring. There? can? happen for various reasons, for example in the case of vibrations, high loads, performance applications, etc.

Finally, the eccentric clamping collar equipped with a set screw is not suitable for applications where the rotating shaft can? work in both directions of rotation. In such situations, it is preferable to use a solution without a clamping collar, according to which the radially internal ring is directly blocked on the rotating shaft by means of a pair of pressure screws. This solution also has drawbacks, since it complicates the machining of the radially inner ring.

Is there therefore the need to define a? unit? bearing provided with a clamping collar in such a way that the clamping is reliable from the point of view of mechanical strength, does not cause excessive noise and/or vibrations and is sustainable from an economic point of view.

Summary of the invention

Purpose of the present invention? to create a? unit? bearing comprising a clamping collar provided with characteristics that make the tightening more? effective and therefore free from the drawbacks described above. In particular, the collar an innovative eccentric clamping collar provided with two pressure screws arranged according to a predetermined angular distance which advantageously turns out to be between 57? and 67? and even more preferably equal to 62?.

In fact, in order to increase the capacity? of taking of? unit? bearing on the shaft, compared to the known solutions ? another pressure screw has been added to the eccentric clamping collar, according to precise dimensional parameters, how will it appear? clear below from the detailed description of the invention.

Therefore, according to the present invention a unit is realized bearing provided with an eccentric clamping collar of the radially internal ring, having the characteristics set forth in the appended claims.

Brief description of the drawings

The invention will come now described with reference to the attached drawings, which illustrate some non-limiting embodiments of the housing element, in which:

- figure 1 shows, in cross section, a unit? bearing provided with an eccentric clamping collar, according to an embodiment of the present invention,

- figure 2 ? a frontal section of the unit? bearing provided with the collar of figure 1, in which the clamping means of the collar are visible, - figure 3 is a cross-sectional view of the eccentric clamping collar of the unit? bearing of figure 1,

- figure 4 ? a frontal section of the eccentric tightening collar of the unit? bearing of figure 1,

- figure 5 shows in cross section, the unit? bearing of figure 1 assembled on a rotating shaft, e

- figure 6 ? a front section of the assembly in figure 5.

Detailed description

With reference now to the aforesaid figures, an embodiment of a unit? bearing according to the present invention.

With particular reference to figure 1, the unit? bearing 10 for applications in the agricultural sector and/or in the manufacturing industry - for example the textile, mining, automotive, food and beverage industries ? can I be interposed, for example, between a rotating shaft and a housing element, not forming part of the present invention, and comprises:

- a radially outer ring 31, stationary,

- a radially internal ring 33, rotating about a central rotation axis Y of the unit? bearing 10,

- at least one crown of rolling elements 32, in this example balls, interposed between the radially outer ring 31 and the radially inner ring 33,

- a rolling element retaining cage 34 to keep the rolling elements of the rolling element crown 32 in position,

- an eccentric clamping collar 20 for locking the radially internal ring on a rotating shaft.

Throughout the present description and in the claims, terms and expressions indicating positions and orientations such as ?radial? and ?axial? do they mean referring to the central rotation axis Y of the unit? bearing 30.

The radially external ring 31? provided with a radially outer raceway 31?, while the radially inner ring 33? provided with at least one radially internal raceway 33? to allow the rolling of the crown of the rolling elements 32 interposed between the radially external ring 31 and the radially internal ring 33. For simplicity? of graphic representation the reference 32 sar? attributed both to the individual spheres and to the crown of spheres. Always for simplicity?, you can? use the term ?sphere? by way of example in the present description and in the attached drawings instead of the term pi? generic ?rolling element? (and the same numerical references will also be used). Some embodiments and the related drawings may provide for the use of rolling elements other than balls (for example rollers) without thereby departing from the scope of the present invention.

The unit bearing 10 ? otherwise? provided with sealing means 35 for sealing the unit? bearing from the external environment.

The unit bearing 10, according to the present invention, therefore comprises an innovative eccentric clamping collar 20, provided with two pressure screws 21, 22 which exert a pressure and therefore gripping force on a rotating shaft S which does not form part of the present invention. Therefore, the eccentric tightening collar 20 has the function of tightening the radially internal ring 33 on the rotating shaft S, making these two elements integral with rotation. Are the two pressure screws 21, 22 arranged according to a predetermined angular distance ? which advantageously turns out to be between 57? and 67? and even more preferably equal to 62?. The use of a second pressure screw? aimed at increasing the capacity of taking of? unit? bearing 10 on the rotating shaft S.

To lock the rotating shaft S with respect to the eccentric clamping collar 20 and therefore with respect to the radially internal ring, ? necessary that the clamping collar and the radially internal ring have some particularities? geometric and dimensional.

In fact, with reference to figures 1 and 2, the radially internal ring 33 has an extremity edge 330 having a circumferentially variable thickness, since said end edge? 330 ? machined by turning its radially outer cylindrical surface 331 to a diameter B having an eccentricity? And with respect to the Y rotation axis of the unit? bearing 10. Preferably the value of the eccentricity? AND ? between 3% and 4% of the value of the diameter C of the radially internal cylindrical surface 332 of the radially internal ring 33.

Furthermore, with reference to figures 3 and 4, the eccentric clamping collar 20 has an end edge 200 having a circumferentially variable thickness, since said end edge? 200 ? machined by turning its radially internal cylindrical surface 201 to a diameter A having the same eccentricity? E with respect to the axis of rotation Z of the eccentric clamping collar 20. The value of? eccentricity? AND ? therefore the same is true for both the radially outer cylindrical surface 331 of the radially inner ring 33 and for the radially inner cylindrical surface 201 of the eccentric clamping collar 20.

The eccentric clamping collar 20 also has two threaded holes 23, 24 having diameters M and M1, preferably equal to each other, and positioned at an angular distance ?. The two pressure screws 21, 22 are screwed into these threaded holes. How is this done? said the angular distance? ? between 57? and 67? and even more preferably equal to 62?. With respect to a vertical axis X (for example the axis of the single pressure screw according to known solutions) of the eccentric clamping collar 20 each hole 23, 24 will have? preferably an angular distance equal to 31?. Therefore the angular position of the holes 23, 24 for the pressure screws 21, 22 according to the present invention ? symmetrical with respect to the single hole for the only pressure screw of the known locking system.

The assembly process? very simple. With reference to figures 5 and 6, ? sufficient to rest the radially internal cylindrical surface 201 of the eccentric tightening collar 20 on the radially external cylindrical surface 331 of the radially internal ring 33 and then rotate the tightening collar 20 until it interferes with the rotating shaft S, creating an area of contact I between a radially internal cylindrical surface 202 of the eccentric clamping collar 20 and the rotating shaft S. Finally the two pressure screws 21, 22 are tightened which will grip the rotating shaft S. The two pressure screws 21, 22 must be positioned exactly opposite the contact area I with a predetermined angular distance ? (as seen between 57? and 67?), so that the resultant Ft of the two forces F1 and F2 generated by the pressure screws 21, 22 is always within the contact area I, making it more? the coupling between the rotating shaft S and the eccentric clamping collar 20 is robust. The angular distance ?, cos? determined allows you to obtain a resultant force of intensity? greater than that obtainable for greater angular distances, for example 120?. On the other hand, lower values of the angular distance would make the locking system according to the present invention less balanced, since the forces acting between the shaft and the inner ring are not equidistant and balanced, and therefore not very suitable for applications in which the shaft can? rotate in both directions of rotation.

This solution overcomes the limit of eccentric clamping collars, i.e. the fact that their use is limited to applications in which the direction of the shaft is ? always the same. In fact, the presence of two pressure screws makes the clamping collar suitable for use even when the rotation of the shaft is ? alternating.

The main advantage of this new locking system? the greater grip strength of the unit? bearing, since? the eccentric clamping strainer ? locked in the most? robust on the rotating shaft. The dimensions of the pressure screws and their tightening torque ? unchanged compared to the single pressure screw solution, but the presence of an additional pressure screw increases the performance of the locking system as a whole.

In addition to the embodiments of the invention, as described above, it should be understood that there are numerous further variants. It must also be understood that said embodiments are only examples and do not limit the object of the invention, nor? its applications, n? its possible configurations. On the contrary, although the above description makes it possible for the skilled man to implement the present invention at least according to an exemplifying configuration thereof, it must be understood that numerous variations of the components described are conceivable, without thereby departing from the object of the description ?invention, as defined in the appended claims, construed literally and/or according to their legal equivalents.

Claims (8)

1.Unit? bearing (10) comprising: - a radially outer ring (31), stationary, - a radially internal ring (33), rotating around a central rotation axis (Y) of the unit? bearing (10), - at least one crown of rolling elements (32) interposed between the radially outer ring (31) and the radially inner ring (33), - an eccentric collar (20) for tightening the radially inner ring (33) on a rotating shaft (S), - a first pressure means (21) on the eccentric collar (20), the unit? bearing (10) being characterized in that the eccentric collar (20) ? equipped with a second means of pressure (22) which increases the capacity? of taking of? unit? bearing (10) on the rotating shaft (S). 2.Unit? bearing (10) according to claim 1, wherein the first pressing means (21) and the second pressing means (22) are set screws. 3.Unit? bearing (10) according to claim 1 or 2, wherein the first pressure means (21) and the second pressure means (22) are arranged at an angular distance (?) between 57? and 67?. 4.Unit? bearing (10) according to claim 3, wherein the first pressure means (21) and the second pressure means (22) are arranged according to an angular distance (?) equal to 62?. 5.Unit? bearing (10) according to one of the preceding claims, wherein the radially inner ring (33) comprises an end edge? (330) and a radially outer cylindrical surface (331) having an eccentricity? (E) with respect to the central rotation axis (Y) of the unit? bearing (10). 6.Unit? bearing (10) according to one of the preceding claims, wherein the eccentric collar (20) comprises an end edge (200) and a radially internal cylindrical surface (201) having eccentricity? (E) with respect to an axis of rotation (Z) of the eccentric collar (20). 7.Unit? bearing (10) according to one of claims 5 or 6, where the eccentricity? (AND) ? comprised between 3% and 4% of the value of the diameter (C) of a radially internal cylindrical surface (332) of the radially internal ring (33). 8. Method of assembling a unit? bearing according to one of claims 1 to 7, comprising the following steps: - rest the radially internal cylindrical surface (201) of the eccentric collar (20) on the radially external cylindrical surface (331) of the radially internal ring (33), - rotate the eccentric collar (20) until it interferes with the rotating shaft (S), creating a contact area (I) between a radially internal cylindrical surface (202) of the eccentric collar (20) and the rotating shaft (S) , - position the first pressure means (21) and the second pressure means (22) opposite the contact area (I) at a predetermined angular distance (?), - tighten the first pressure means (21) and the second pressure means (22) which will grip the rotating shaft (S), so that the forces (F1 and F2) generated by the first pressure means (21) and from the second pressure means (22) are inside the contact zone (I).